Refrigeration system with modulated condensing loops

Information

  • Patent Grant
  • 6502412
  • Patent Number
    6,502,412
  • Date Filed
    Monday, November 19, 2001
    23 years ago
  • Date Issued
    Tuesday, January 7, 2003
    21 years ago
  • Inventors
  • Examiners
    • Esquivel; Denise L.
    • Norman; Marc
    Agents
    • Renault; Ogilvy
    • Houle; Guy J.
Abstract
A refrigeration system having a main refrigeration circuit having a condensing stage, wherein a first refrigerant in a high pressure gas state is condensed at least partially to a liquid state. The condensing stage has a pair of stand-alone condensing stage closed loops in heat exchange relation with the main refrigeration circuit. The stand-alone condensing stage closed loops are parallel one to another and each comprise a second refrigerant circulating between at least a heat absorption stage, wherein the second refrigerant absorbs heat from the first refrigerant in the main refrigeration circuit so as to condense the first refrigerant to the liquid state, and a heat release stage, wherein the second refrigerant releases the absorbed heat. The condensing stage has modulating valves for selectively and quantitatively modulating the temperature of said first refrigerant and compressor head pressure.
Description




FIELD OF THE INVENTION




The present invention generally relates to refrigeration systems, and more particularly, to modulate closed condensing loops for use therewith.




BACKGROUND OF THE INVENTION




In a typical refrigeration system, particularly those found in supermarkets, a plurality of evaporators are used to refrigerate foodstuff in refrigerated display cases. Such systems basically comprise a closed circuit having a compressor stage, a condenser stage, an expansion stage and an evaporator stage. Other stages may be added to the above described basic refrigeration circuit in order to recuperate heat, or to provide refrigeration systems with defrosting loops for high speed defrosting of the evaporators. For instance, U.S. Pat. No. 5,673,567, issued on Oct. 7, 1997 to the present assignee, discloses a refrigeration system with a heat reclaim loop for recuperating heat from hot high pressure refrigerant gas outletting from the compressor stage, rather than evacuating the heat through the condensers, where the heat would be lost to the atmosphere. Thus, the heat reclaim loop is provided in parallel to the condenser stage in order to recuperate heat in heat exchange devices rather than rejecting it to the atmosphere. Preferably, in the cooler seasons, the heat is used for heating the entrance area and other specific colder areas of supermarkets. In the warmer months, the heat may be recuperated for heating water.




U.S. Pat. No. 5,826,433, issued on Oct. 27, 1998 to the present assignee, discloses modification to the above described patent, whereby a modulating valve is provided for efficiently controlling the rate of heat reclaim versus the heat rejection through the condenser stage.




Finally, U.S. Pat. No. 6,089,033, issued on Jul. 18, 2000 to the present assignee discloses a refrigeration system configuration in order to defrost evaporator units at higher speeds.




These refrigeration systems, and generally most refrigeration systems used in supermarkets, have roof top condensers in order to reject heat at the outlet of the compressor stage, whereby the refrigerant is condensed at least partially to a liquid state. Unfortunately, the loops to the roof top condensers extend the piping length of the refrigeration system. Accordingly, the piping networks of refrigeration systems are filled with refrigerant to provide every stage with the necessary conditions for refrigeration. Furthermore, with the advent of heat reclaim loops and high speed defrost cycles, even more refrigerant is used.




Unfortunately, the refrigerants typically used in such refrigeration systems (i.e. refrigerants 404, 408, 507, AZ-20 and the like) are expensive and are often volatile, whereby they may be hazardous to human health and to the environment. The more these refrigerants are used, the higher is the risk of polluting the environment.




SUMMARY OF THE INVENTION




It is a feature of the present invention to provide a refrigeration systems having reduced amounts of the above stated refrigerants.




It is a further feature of the present invention to provide a refrigeration system optimizing heat reclaim with respect to compressor operation.




According to the above feature of the present invention, and from a broad aspect thereof, the present invention provides a refrigeration system having a main refrigeration circuit having a condensing stage, wherein a first refrigerant in a high pressure gas state is condensed at least partially to a liquid state. The condensing stage has a pair of stand-alone condensing stage closed loops in heat exchange relation with the main refrigeration circuit. The stand-alone condensing stage closed loops are parallel one to another and each comprise a second refrigerant circulating between at least a heat absorption stage, wherein the second refrigerant absorbs heat from the first refrigerant in the main refrigeration circuit so as to condense the first refrigerant to the liquid state, and a heat release stage, wherein the second refrigerant releases the absorbed heat. The condensing stage has modulating valves for selectively and quantitatively modulating the temperature of said first refrigerant and compressor head pressure.











BRIEF DESCRIPTION OF THE DRAWINGS




A preferred embodiment of the present invention will now be described in detail having reference to the accompanying drawings in which:





FIG. 1

is a schematic diagram illustrating a stand-alone evaporative condenser loop of the present invention;





FIG. 2

is a schematic diagram depicting a stand-alone heat reclaim loop of the present invention; and





FIG. 3

is a schematic diagram illustrating a refrigeration system having the stand-alone evaporative condenser loop and heat reclaim loop.











DESCRIPTION OF PREFERRED EMBODIMENTS




Referring to

FIG. 1

, there is generally shown at


10


a stand-alone evaporative condenser loop of the present invention. The loop


10


comprises a plate heat exchanger


12


for the heat exchange between a refrigerant A in a refrigeration system and a refrigerant B in the evaporative condenser loop


10


. Refrigerant A of the refrigeration system entering the heat exchanger


12


is from the output of compressors in a high pressure hot gas state, and goes through the heat exchanger


12


to release latent heat by condensing, to then exit therefrom at least partially in a high pressure liquid state. Thus, a gas refrigerant line from the refrigeration system is shown entering the heat exchanger


12


through inlet line I, whereas a liquid refrigerant line exits the heat exchanger


12


at outlet line O. The refrigeration system will be described in further detail hereinafter.




The condensing loop


10


has an evaporative condenser


14


. The evaporative condenser


14


typically comprises a coiling system therein, across which a fluid flows in order for refrigerant within the coiling system to release heat it has previously absorbed in the heat exchanger


12


. For instance, the fluid may be air or a spray of water flowing over the coiling system. A condenser feedline


16


connects the heat exchanger


12


to the evaporative condenser


14


. It is pointed out that the condensing loop


10


may be provided with a plurality of evaporative condensers


14


, wherefore a branch line


18


is shown diverging from the condenser feedline


16


to add similar evaporative condensers


14


in parallel to the first one. The condenser feedline


16


is provided with valves and control devices to ensure the flow direction and the proper refrigerant conditions. For instance, a manometer


20


is shown mounted in the condenser feedline


16


, as well as a plurality of check valves


22


.




A condenser return line is generally shown at


24


and connects the evaporative condenser


14


to the heat exchanger


12


, so as ensure the flow of cooled refrigerant from the evaporative condenser


14


to the heat exchanger


12


. A pump


26


is provided in the condenser return line


24


to ensure the flow of the refrigerant B in the condensing loop


10


. A filter


28


in the condenser return line


24


filters out the refrigerant. Further check valves


22


and manometer


20


are provided in the condenser return line


24


. Furthermore, parallel loops (not shown) along with manually operated valves (e.g. three-way valves, ball valves, butterfly valves) may also be provided in order to isolate the various components of the condensing loop


10


for maintenance or for servicing purposes. A branch line


30


is shown connecting to the condenser return line


24


in the event where more than one evaporative condenser


14


are part of the condensing loop


10


.




Referring now to

FIG. 2

, a stand-alone heat reclaim loop in accordance with the present invention is generally shown at


50


. The heat reclaim loop


50


comprises a plate heat exchanger


52


, provided for absorbing heat from a refrigerant A in a refrigeration system. The refrigerant A in the refrigeration system is in a high pressure hot gas state when entering the heat exchanger


52


and is condensed to a liquid state to then exit the heat exchanger


52


. The inlet line of hot pressure gas refrigerant A is shown at I


2


, whereas the outlet of condensed liquid refrigerant A is shown at outlet line O


2


.




The heat reclaim loop


50


has a heat reclaim coil


54


and a air heating unit


56


. The heat reclaim coil


54


is typically installed in a ventilation duct through which air circulates, so as to warm up the air. The air heating unit


56


is typically provided for heating areas where ventilation is not required (e.g. shipping dock, entrance). It is pointed out that the heat reclaim loop


50


may be limited to either one of the heat reclaim coil


54


and the heating unit


56


, or may even have a plurality of both. A heat reclaim feedline


58


connects the heat exchanger


52


to the heat reclaim coil


54


and to the air heating unit


56


to ensure the flow of a refrigerant B therebetween. An accumulation tank


60


is connected in the heat reclaim feedline


58


for accumulating refrigerant B having absorbed heat in the heat exchanger


52


. A pump


62


is also mounted in the heat reclaim feedline


58


, downstream from the accumulation tank


60


to ensure the flow of refrigerant B from the accumulation tank


60


to the heat reclaim coil


54


and the air heating unit


56


. A heat reclaim return line


64


connects the heat reclaim coil


54


and the air heating unit


56


to the heat exchanger


52


, thereby ensuring the flow of refrigerant B from the formers to the latter.




The heat reclaim coil


54


has an inlet line


66


separated from the heat reclaim feedline


58


by a three-way valve


68


. A by-pass line


70


is connected to the free port of the three-way valve


68


and converges with an outlet line


72


of the heat reclaim coil


54


to reach the heat reclaim return line


64


. Thus, the three-way valve


68


controls the flow of refrigerant B from the heat reclaim feedline


58


to the heat reclaim coil


54


. The three-way valve


68


may be fully closed to the inlet line


66


of the heat reclaim coil


54


, whereby refrigerant B flows through the by-pass line


70


to reach the heat reclaim return line


64


. It is pointed out that the outlet line


72


comprises a check valve


74


such that refrigerant by-passing the heat reclaim coil


54


is prevented from entering same through the outlet line


72


thereof.




The air heating unit


56


is connected to the heat reclaim loop


50


in parallel to the heat reclaim coil


54


. The heating unit


56


has an inlet line


76


connected to the heat reclaim feedline


58


through a three-way valve


78


. The free port of the three-way valve


78


is connected to a by-pass line


80


which converges with an outlet line


82


of the heating unit


56


to connect to the heat reclaim return line


64


. Similarly to the heat reclaim coil


54


, the flow of refrigerant B to the heating unit


56


is controlled by the three-way valve


78


. Once more, the heating unit


56


may be by-passed by the refrigerant B, whereby refrigerant B circulates through the by-pass line


80


and is prevented from entering the heating unit


56


by the check valve


84


mounted therein.




The pump


62


and the accumulation tank


60


allow storage of refrigerant B, having absorbed heat in the heat exchanger


52


. If the heat reclaim coil


54


and the air heating unit


56


are in standby (by being by-passed) as the demand for heating air is low, the tank


60


accumulates the heated refrigerant B such that the heat reclaim loop


50


is able to sustain sudden and rapid increases in demand of heating air. The pump


62


may stop operating beyond certain levels of refrigerant B. It is pointed out that the accumulation tank


60


may be insulated to keep the refrigerant therein in given states. The pump


62


may be automated in order to operate automatically according to factors such as outdoor and indoor temperatures, as well as refrigerant B temperature. Increased refrigerant B demand may thus be anticipated and fulfilled by the pump


62


and the accumulation tank


60


.




The heat reclaim loop


50


comprises various devices for the control of the refrigerant parameters, such as the direction of flow, the pressure and the filtering. For instance, filter


86


, check valves


88


and manometers


90


are provided in the heat reclaim loop


50


for the above described reasons.




Now that both the stand-alone evaporative condenser loop


10


and heat reclaim loop


50


have been described in detail, a typical refrigeration system in which the formers may be used will now be described. Because the stand-alone condensing loops use non-polluting refrigerants such as glycol, there is a reduction in the quantity of refrigerant required in the conventional portion of the refrigeration system.




Referring now to

FIG. 3

, a refrigeration system


100


is typically adapted for receiving the stand-alone evaporative condenser loop


10


described in FIG.


1


and the heat reclaim loop


50


described in FIG.


2


. The evaporative loop


10


and the heat reclaim loop


50


are shown connected to the refrigeration system


100


parallel one to another. Similarly to the description of the loops


10


and


50


, for clarity purposes, a refrigerant, identified as refrigerant A, which will be discussed hereinafter, flows in the refrigeration system


100


, whereas a refrigerant, referred to as refrigerant B, flows in the loops


10


and


50


. Furthermore, as the invention resides in the portion of the refrigeration system involving the stand-alone evaporative condenser loop


10


and the stand-alone heat reclaim loop


50


, which have been described extensively above, the refrigeration system


100


will only be described schematically. For instance, the refrigeration system


100


shown in

FIG. 3

comprises high speed defrost loops which will not be described herein.




As shown in

FIG. 3

, the refrigeration system


100


comprises a plurality of compressors


102


. Refrigerant A from compressors


102


is in a high pressure gas state. A header


106


and a high pressure gas line


108


are connected to the outlets of the compressors


102


so as to convey the high pressure gas refrigerant A exiting therefrom to a three-way control valve


104


and modulating valves


105


and


107


, which separates the high pressure gas line


108


into an evaporative condenser line


110


and a heat reclaim line


112


. Both the evaporative condenser line


110


and the heat reclaim line


112


will converge to a liquid refrigerant reservoir


114


, after having high pressure gas refrigerant A gone through heat exchangers


12


and


52


of the evaporator condenser loop


10


and the heat reclaim loop


50


, respectively. Therefore, as the evaporative condenser line


110


and the heat reclaim line


112


diverge at the valves


104


,


105


and


107


and converge at the refrigeration reservoir


114


, these lines are parallel one to another. It is pointed out that the evaporative condenser line


112


was referred to as input line I and output line O in

FIG. 1

, wherefore reference letters I and O have been added to FIG.


3


. Similarly, the heat reclaim line


112


was referred to in

FIG. 2

as inlet line I


2


and outlet line O


2


, wherefore reference letters for the latters have been added to FIG.


3


.




The three-way control valve


104


and the modulating valves


105


and


107


are adapted to control the amounts of refrigerant A flowing to the evaporative condenser line


110


and the heat reclaim line


112


. A main objective of the refrigeration system


100


is to recuperate as much heat as possible from the refrigerant A requiring to be condensed at least partially to a liquid state. However, in order to keep the operation costs low for such a refrigeration system, the compressor


102


must operate with the head pressures as low as possible, yet by fulfilling the compression needs of the system. By the use of parallel condenser line


110


and heat reclaim line


112


, it is possible to optimize the head pressure of the refrigerant A in the main refrigeration system


100


. According to a plurality of factors which will be described hereinafter, the three-way control valve


104


and the modulating valves


105


and


207


can completely shut the feeding of high pressure gas refrigerant A to either one of the heat exchanger


12


and heat exchanger


52


, as well as modulate and control the output pressure of the compressor


102


. As mentioned in the description of the evaporative condenser loop


10


and the heat reclaim loop


50


, the high pressure gas refrigerant A exiting the heat exchangers


12


and


52


, respectively, through outlet lines O and O


2


, is in a high pressure liquid state.




Typically, the head pressure in the condenser line


110


floats in order to maintain the pressure of refrigerant A in this portion of the refrigeration system at a relatively low pressure. As the evaporative condenser loop


10


has great cooling capacities due to the use of water to cool refrigerant B, which then cools refrigerant A through heat exchanger


12


, the condenser line


110


allows lowering of the output refrigerant A pressure of the compressors


102


, thereby resulting in energy savings. Modulating valves


105


and


107


modulate the output pressure of the compressors


102


. One, for instance, may operate at lower pressures, whereas the other works at higher pressures. The pressure of refrigerant A varies according to a few factors. The compressors must operate as little as possible, as they increasingly consume electricity as a function of their pressure output. On the other hand, the refrigerant released from the compressors


102


must be at a temperature above that of the cooling fluid, usually a predetermined constant pressure differential (e.g., +15° C.). In the present invention, the cooling fluid is refrigerant B, which is actually cooled by the ventilation air in the heat reclaim coil


54


or the heating unit


56


in the case of the heat reclaim line


112


, and by water in the evaporative condenser


14


in the case of the evaporative condenser line


10


. Therefore, the temperature and pressure of the refrigerant A are modulated in accordance with the heat reclaim demand, the indoor air temperature and the outdoor air temperature.




Thereafter, high pressure liquid refrigerant A accumulated in the liquid refrigerant reservoir


114


flows through a liquid refrigerant line


116


and liquid refrigerant header


118


to reach the expansion valves


120


of the refrigeration system


100


. High pressure liquid refrigerant A flowing across the expansion valves


120


expands to be lowered in pressure. Therefore, refrigerant A, in a low pressure liquid state, flows to evaporators


122


through evaporator inlet lines


124


, which extend between the expansion valves


120


and the evaporators


122


. The low pressure liquid A is at a temperature well below the desired temperature of the refrigerator units (not shown). The refrigerant A absorbs heat in the evaporators


122


, whereby it exits the evaporators


122


in a gas state. The low pressure liquid refrigerant A exits the evaporators


122


in evaporator outlet lines


126


to reach a suction header


128


to then return to the compressors


102


.




Typical refrigerants used as refrigerant A are refrigerants 404, 408, 507, AZ-20. The typical refrigerants used as refrigerant A may be volatile, whereby they are a threat to the environment as they evaporate at ambient conditions. Furthermore, they are toxic and are likely hazardous to health. The evaporative condenser loop


10


and the heat reclaim loop


50


allow for the reduction of size of the refrigeration system


100


. Typically, the evaporative condenser line


110


and the heat reclaim line


112


extend from the compressors


102


to the roof top of the building to reach condensers of the condenser stage, wherein heat is released to the environment. Accordingly, these lengthy networks of piping must be filled with refrigerant A for the proper functioning thereof.




The stand-alone evaporative condenser loop


10


and heat reclaim loop


50


extend from adjacent the compressors


102


to the various condensing units thereof, namely the evaporative condenser


14


, the heat reclaim coil


54


and the air heating unit


56


. Therefore, the evaporative condenser line


110


and the heat reclaim line


112


are substantially shortened, whereby the amount of refrigerant A in the refrigeration system


100


is greatly reduced. As the refrigerant B must not sustain great variations in temperature as compared to the refrigerant A which must rise above the outdoor temperature to condense and drop below the refrigerator temperature to evaporate, the sole purpose of the refrigerant B is to absorb heat to condense the refrigerant A. Therefore, refrigerant B may be any of the following: ethylic acetate, acetic acid, sulfuric acid, ammoniac, calcium chloride, hydrogen chloride, methylene chloride, sodium chloride, vinyl chloride, carbon dioxide, ethanol, ethylene glycol, acetate formiate, potassium formiate, iso-butane, Pekasol 50, propane, propylene glycol, toluene, trichloroethylene. In any event, refrigerant B is chosen amongst safer fluids than refrigerant A. As the piping of the refrigeration system


100


is greatly reduced, the compressors


102


are not required to outlet compressed refrigerant at pressures as high as for longer refrigeration lines. The compressors can operate at head pressures of about 120 psi instead of 220 psi, thereby reducing their operating time and increasing their life-span. Therefore, substantial savings are achieved in electricity consumption of the compressors


102


, and the life of the compressors


102


is increased.




The three-way control valve


104


and the modulating valves


105


and


107


redirect the flow of refrigerant A towards heat exchanger


12


or heat exchanger


52


according to the seasonal heat requirements of the building in which the refrigeration system


100


is. The stand-alone heat reclaim loop


50


advantageously recuperates the heat produced by the compressors


102


. The evaporative condenser


14


of the stand-alone evaporative condenser loop


10


may either release the heat outdoors, or recover the heat by, for instance, spraying a liquid such as water on the coils of the evaporative condenser


14


to absorb the excess heat. Thus, in the fall, winter and spring seasons, a greater amount of refrigerant is circulated in the heat exchanger


52


, whereby the heat absorbed from refrigerant A will serve for heating the building. It is pointed out that the refrigeration system


100


may be provided with only one of the evaporative condenser loop


10


or the heat reclaim loop


50


.




It is within the ambit of the present invention to cover any obvious modifications of the embodiments described herein, provided such modifications fall within the scope of the appended claims.



Claims
  • 1. A refrigeration system having a main refrigeration circuit, wherein a first refrigerant goes through at least a compressing stage, wherein said first refrigerant is compressed to a high pressure gas state to then reach a condensing stage, wherein said high pressure gas refrigerant is condensed at least partially to a liquid state to then reach an expansion stage, wherein said high pressure liquid refrigerant is expanded to a low pressure liquid state to then reach an evaporator stage, wherein said low pressure liquid refrigerant is evaporated at least partially to a low pressure gas state by absorbing heat, to then return to said compressing stage, said condensing stage having at least a pair of stand-alone condensing stage closed loops in heat exchange relation with said main refrigeration circuit, said stand-alone condensing stage closed loops being parallel one to another and each comprising a second refrigerant circulating between at least a heat absorption stage, wherein said second refrigerant absorbs heat from said first refrigerant in said main refrigeration circuit so as to condense said first refrigerant to said liquid state, and a heat release stage, wherein said second refrigerant releases said absorbed heat, said condensing stage having modulating valve means for selectively and quantitatively modulating the temperature of said first refrigerant and compressor head pressure.
  • 2. The refrigeration system according to claim 1, wherein said second refrigerant is one of ethylic acetate, acetic acid, sulfuric acid, ammoniac, calcium chloride, hydrogen chloride, methylene chloride, sodium chloride, vinyl chloride, carbon dioxide, ethanol, ethylene glycol, acetate formiate, potassium formiate, iso-butane, Pekasol 50, propane, propylene glycol, toluene, and trichloroethylene.
  • 3. The refrigeration system according to claim 1, wherein said heat exchange relation between said main refrigeration circuit and said condensing stage closed loops is achieved by plate heat exchangers.
  • 4. The refrigeration system according to claim 1, wherein said heat release stage of a first of said closed loops comprises at least one of a heat reclaim coil and a heating unit, and a second one of said closed loops comprises an evaporative condenser.
  • 5. The refrigeration system according to claim 4, wherein said heat release stage of said first of said closed loops comprises valves to selectively chose flow of said second refrigerant through at least one of said heat reclaim coil and said heating unit.
  • 6. The refrigeration system according to claim 1, wherein absorbed heat from said second refrigerant in said heat release stage is released by at least one of being evacuated outdoors, heating water and heating air.
  • 7. The refrigeration system according to claim 6, further comprising valves for selecting the releasing of said absorbed heat from said second refrigerant in said heat release stage.
  • 8. The refrigeration system according to claim 1, further comprising an absorbed heat reservoir downstream from said heat absorption stage in said first of said closed loops, wherein said second refrigerant is accumulated prior to being fed to said heat release stage.
  • 9. The refrigeration system according to claim 1, wherein said modulating valve means comprises at least a valve for selectively and quantitatively directing flow of said first refrigerant for heat exchanging with said closed loops.
  • 10. The refrigeration system according to claim 9, wherein said modulating valve means comprises two modulating valves and a three-way directional valve connecting said compressing stage to said condensing stage.
  • 11. A refrigeration system having a main refrigeration circuit, wherein a first refrigerant goes through at least a compressing stage, wherein said first refrigerant is compressed to a high pressure gas state to then reach a condensing stage, wherein said high pressure gas refrigerant is condensed at least partially to a liquid state to then reach an expansion stage, wherein said high pressure liquid refrigerant is expanded to a low pressure liquid state to then reach an evaporator stage, wherein said low pressure liquid refrigerant is evaporated at least partially to a low pressure gas state by absorbing heat, to then return to said compressing stage, said condensing stage having at least a pair of stand-alone condensing stage closed loops in heat exchange relation with said main refrigeration circuit, said stand-alone condensing stage closed loops being parallel one to another and each comprising a second refrigerant circulating between at least a heat absorption stage, wherein said second refrigerant absorbs heat from said first refrigerant in said main refrigeration circuit so as to condense said first refrigerant to said liquid state, and a heat release stage, wherein said second refrigerant releases said absorbed heat, said condensing stage having modulating valve means for selectively and quantitatively modulating the temperature of said first refrigerant and compressor head pressure as a function of at least one of an outdoor temperature and an indoor ambient temperature.
  • 12. The refrigeration system according to claim 11, wherein said second refrigerant is one of ethylic acetate, acetic acid, sulfuric acid, ammoniac, calcium chloride, hydrogen chloride, methylene chloride, sodium chloride, vinyl chloride, carbon dioxide, ethanol, ethylene glycol, acetate formiate, potassium formiate, iso-butane, Pekasol 50, propane, propylene glycol, toluene, and trichloroethylene.
  • 13. The refrigeration system according to claim 11, wherein said heat exchange relation between said main refrigeration circuit and said condensing stage closed loops is achieved by plate heat exchangers.
  • 14. The refrigeration system according to claim 11, wherein said heat release stage of a first of said closed loops comprises at least one of a heat reclaim coil and a heating unit, and a second one of said closed loops comprises an evaporative condenser.
  • 15. The refrigeration system according to claim 14, wherein said heat release stage of said first of said closed loops comprises valves to selectively chose flow of said second refrigerant through at least one of said heat reclaim coil and said heating unit.
  • 16. The refrigeration system according to claim 11, wherein absorbed heat from said second refrigerant in said heat release stage is released by at least one of being evacuated outdoors, heating water and heating air.
  • 17. The refrigeration system according to claim 16, further comprising valves for selecting the releasing of said absorbed heat from said second refrigerant in said heat release stage.
  • 18. The refrigeration system according to claim 11, further comprising an absorbed heat reservoir downstream from said heat absorption stage in said first of said closed loops, wherein said second refrigerant is accumulated prior to being fed to said heat release stage.
  • 19. The refrigeration system according to claim 11, wherein said modulating valve means comprises at least a valve for selectively and quantitatively directing flow of said first refrigerant for heat exchanging with said closed loops.
  • 20. The refrigeration system according to claim 19, wherein said modulating valve means comprises two modulating valves and a three-way directional valve connecting said compressing stage to said condensing stage.
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